Alkali metal titanates, and electrodes and batteries based on the same

ABSTRACT

Disclosed is a lithium titanate material, which may include an additive, and its use as an electrode in a battery. Specifically disclosed is a lithium titanate based material, with primary particle size larger than 100 nm, having very good high rate charge and discharge capabilities when incorporated into a lithium battery.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation-in-part of U.S. patent applicationSer. No. 11/757,658 filed Jun. 4, 2007, which claims priority of U.S.Provisional Patent Application Ser. No. 60/810,942 filed Jun. 5, 2006,entitled “Alkali Metal Titanates and Methods for Their Synthesis”; andU.S. Provisional Patent Application Ser. No. 60/822,675 filed Aug. 17,2006, entitled “Doped Lithium Titanate Material and Methods for ItsManufacture”, all of which are incorporated herein by reference.

FIELD OF THE INVENTION

This invention relates generally to alkali metal titanates, and moreparticularly to lithium titanates. More specifically, the inventionrelates to lithium titanates with superior electrochemical properties,and more particularly with superior rate capabilities when incorporatedinto lithium batteries.

BACKGROUND OF THE INVENTION

Alkali metal titanates have electrochemical properties which make themdesirable as electrode materials for a variety of devices. Lithiumtitanate (Li₄Ti₅O₁₂ or LTO) has been found to have particular utility asan electrode material for lithium batteries. It is a relatively low-costmaterial, and exhibits high performance characteristics in lithiumbatteries; consequently, it is anticipated to have significant utilityas an electrode material for high performance, high power batteries suchas those utilized in hybrid electric vehicles and other high powerapplications.

One important characteristic of high power, high performance batteriesis rate capability. That is, the rate at which the batteries can take upand deliver an electrical charge. This parameter is particularlyimportant under high charge/discharge rates as are encountered inelectric vehicles and other high power applications.

First cycle reversibility is another very important parameter forrechargeable lithium batteries. This parameter measures the decline instorage capacity when a freshly manufactured lithium battery isinitially cycled. Manufacturers compensate for this initial loss bybuilding extra capacity into batteries. However, this approach increasesthe size and cost of batteries, and industry has always sought to limitmagnitude of first cycle reversibility.

Various lithium titanate materials are commercially available and areutilized in the manufacture of lithium batteries. However, heretoforeavailable commercial materials produce lithium batteries having firstcycle reversibilities of approximately 80%, which represents asignificant inefficiency. In addition, prior art batteries incorporatinglithium titanate materials suffer from problems of high rate charge anddischarge capacities, and these limitations are a significant detrimentto their use in high power applications for electric vehicles, powertools and the like. In an effort to improve high rate performance, theprior art has believed that lithium titanate spinel materials havingextremely high surface areas and correspondingly small particle sizes,typically in the nanoscale regime below 100 nanometers, must be employedin order to obtain good high rate performances. Such materials aredisclosed, for example, in U.S. Pat. No. 7,211,350. Conventional wisdomin the prior art is that high rate capability cannot be expected fromlarger particle size and correspondingly lower specific surface areamaterials. Processes for the preparation of high surface area, nanoscalelithium titanate materials as well as processes and structures for theirincorporation into battery systems are complex, expensive and difficultto implement. Therefore, it will be appreciated that there is a need inthe art for improved lithium titanate electrode materials which canprovide good performance characteristics in terms of high ratecapacities and improved first cycle reversibilities in batteriesincorporating such materials. In addition, such materials and batteriesshould be simple and economical to fabricate and utilize. As will beexplained in detail hereinbelow, the present invention provides improvedlithium titanate materials which manifest very good performancecharacteristics even when implemented in particle size formats outsideof the prior art nanoscale range. These and other advantages of theinvention will be apparent from the drawings, discussion and descriptionwhich follow.

SUMMARY OF THE INVENTION

Disclosed is a lithium titanate material having an average particle sizeof at least 100 nm. In some instances, the material has an averageparticle size of at least 150 nm, and in specific instances, theparticles of the material fall in the general size range of 150-500 nm.The material has a correspondingly low surface area, and in general thematerial has a surface area, as measured by the BET method, of no morethan 20 m²/g, and in some instances no more than 15 m²/g. In particularimplementations, the material has a BET surface area of approximately3-7 m²/g. The material may be prepared in pristine form or compositeform incorporating additives, and in some instances, the additive maycomprise a transition metal, with Zr being one specific transition metalutilized in some embodiments.

The material is further characterized by having low agglomeration. Thematerial has a pore size distribution such that it includes a firstdistribution of pore sizes in the range of 0.1-1 micron (and inparticular instances 0.2-0.6 microns); and a second distribution of poresizes in the range of 1-100 microns (and in particular instances 5-50microns). The total volume of the pores of the first size distributionis greater than those of the second size distribution. In particularinstances, the volume pores of the first size distribution will comprise45-60% of the total pore volume and those of the second distributionwill comprise 25-40% of the total volume. Materials of the presentinvention, when incorporated into battery systems, manifest very goodhigh rate charge and discharge capabilities together with very goodfirst cycle reversibilities.

Also disclosed is a lithium titanate composite material incorporatingadditives. In particular instances, the additive may comprise atransition metal, and this metal may be one or more of V, Zr, Nb, Mo,Mn, Fe, Cu, and Co. The additive may be present in amounts up to 20weight percent, and in specific instances in the range of 0.1-5 weightpercent. In a particular instance, the additive comprises Zr.

The composite material is further characterized by having the form ofparticles with more faceted shape than the pristine material.

Further disclosed are electrodes which include alkali metal titanates inaccord with the foregoing, as well as batteries in which theseelectrodes comprise the anodes.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a graph illustrating the first cycle capacity loss of a priorart cell and a cell which incorporates the present lithium titanatematerial;

FIG. 2 is a graph showing the charge capacity of a particular materialas a function of rate;

FIG. 3 is a chart comparing the rate performance of materials of thepresent invention with those of the prior art.

FIG. 4 is a graph showing the capacity retention of a cell whichincorporates a lithium titanate anode;

FIG. 5 is a graph showing the cycle life of the cell of FIG. 4;

FIG. 6 is a graph showing the SEM images of materials of the presentinvention;

FIG. 7 is a graph showing the TEM images of materials of the presentinvention; and

FIG. 8 is a graph showing the SEM images (left) and porosity analysis(right) of electrodes including materials of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

In accord with one aspect of the invention there is provided a lithiumtitanate composite material. Generally, lithium titanate is recognizedas having the formula Li₄Ti₅O₁₂; however, as is recognized in the art,the stoichiometry of this material may, in some instances, vary withoutsignificantly altering the fundamental nature of the material. Suchvariations may be resultant from a slight oxidation or reduction of thematerial, minor variations of the LiTi ratio and the presence of addingspecies. Accordingly, within the context of this disclosure, all of suchstoichiometric and non-stoichiometric materials are encompassed withinthe definition of lithium titanate.

In a specific group of embodiments, the lithium titanate is preparedfrom a starting material that includes a transition metal in an amountup to approximately 20 weight percent, and some such transition metalsinclude one or more of V, Zr, Nb, Mo, Mn, Fe, Cu, and Co. In oneparticular instance, as is discussed herein, the additive comprises Zr,and in particular instances is present in an amount of 0.1-5 weightpercent of the material. The transition metal may aid in controlling themorphology of the material and/or it may act as a dopant or modifier.

There is a fairly large body of prior art directed to the synthesis oflithium titanate materials, and various processes known in the art maybe utilized to prepare the lithium titanate composite materialsdescribed above. While such prior art processes may be utilized, it hasfurther been found in accord with the present invention that very highquality alkali metal titanates, both in pristine form and compositeform, can be prepared by a process disclosed in U.S. patent applicationSer. No. 11/757,658, June 2007, incorporated herein by reference, whichinvolves impact milling of the starting materials to produce an intimatemixture. In a typical procedure, the starting materials will include asource of lithium such as lithium carbonate and a source of titaniumsuch as titanium dioxide. When an additive is incorporated in thematerial an appropriate amount of a precursor is added to the mixture.For example, when the composite material includes zirconium, a compoundsuch as zirconium acetate, carbonate, chloride, alkoxide or the like maybe added. This mixture is then reacted at elevated temperatures toproduce the alkali metal titanate.

It has been found that materials of the present invention can besynthesized in the form of particles larger than 100 nm which canprovide performance characteristics equal to, or exceeding those oftprior art nanoscale titanate materials. In that regard, the materials ofthe present invention may comprise lithium titanate spinels in the formof particle aggregates having a specific surface area of 3-7 m²/g asmeasured by the BET method. The material has a pore size distributionsuch that it includes a first distribution of pore sizes in the range of0.1-1 micron (and in particular instances 0.2-0.6 microns); and a seconddistribution of pore sizes in the range of 1-100 microns (and inparticular instances 5-50 microns). The total volume of the pores of thefirst size distribution is greater than those of the second sizedistribution. In particular instances, the volume pores of the firstsize distribution will comprise 45-60% of the total pore volume andthose of the second distribution will comprise 25-40% of the totalvolume. The lower surface area of the materials of present inventionallows the present materials to be more stable and safer than the priorart nano material in an electrochemical environment. The lower surfacearea of the materials of present invention also allows the presentmaterials, when incorporated into electrodes, to be pressed into denserforms. Thus higher specific energy can be achieved from the batteriesutilizing the present lithium titanate materials. As will be explainedin further detail, these materials can be incorporated into batterieswhich have very high rate capabilities and low first cycle losses.

In an experimental series, materials of the present invention wereprepared in accord with the synthesis method set forth hereinabove, andtheir performance characteristics, when incorporated into test cells,were compared with those of conventional lithium titanate materials,including those having nanoscale particle sizes.

In a first evaluation, a series of half cells including lithium titanatematerials of the present invention and prior art nano lithium titanatematerials were prepared and the first cycle capacity loss of the cellswere measured, and the results thereof are shown in FIG. 1. As will beseen, these cells utilizing present materials demonstrated a first cyclecapacity loss of approximately 5%, as compared to typical losses ofapproximately 20% in similar cells prepared utilizing commerciallyavailable nano lithium titanate anode materials.

In another evaluation, a series of half cells including lithium titanatematerials of the present invention were prepared and discharged(lithiated) under CCCV mode operation (2.2 to 0.8V, 1 C constant currentand tapering at 0.8V to C/2), then charged (delithiated) to 2.2V undervarious current (C-rate) conditions. As is summarized in FIG. 2, thematerials of the present invention show extremely high rate delithiationcapability, for example as high as 90% of initial capability at 50 C and65% at 100 C.

In a further evaluation, the thus prepared lithium titanate half cellswere compared with corresponding cells fabricated from prior artnanoscale lithium titanate material as well as conventionalnon-nanoscale prior art lithium titanate materials. The materials of thepresent invention were tested in both pristine and composite form. Inthis evaluation, both discharge and charge processes of the cells werein a constant current mode at various C-rates. For instance, a cell isdischarged and charged both at C/2, and then discharged and charged bothat 1 C, and further discharged and charged both at higher rates up to 50C. The data from this experimental series is summarized in FIG. 3. Aswill be seen, the materials of the present invention outperform those ofthe prior art under all conditions, and at very high rate conditions,the composite material of the present invention which has been preparedwith approximately 1% of a Zr additive provides distinctly superiorperformance.

The Li ion cells which include lithium titanate anodes of presentinvention, and A123 proprietary nano-phosphate cathodes were preparedand evaluated. FIG. 4 shows the rate capability of cells preparedutilizing the present lithium titanate materials. As will be seen, thecell of FIG. 4 shows an excellent rate capability with 98% capacityretention at a 20 C discharge rate, and 91% capacity retention at a 50 Crate. Cells of this type have excellent utility in high power, highperformance applications.

FIG. 5 shows the cycle life of a cell of the type illustrated withreference to FIG. 4 and depicts discharge capacity retention as afunction of charge/discharge cycles carried out at 3 C/−3 C. As will beseen, this cell retains over 90% of its capacity after 6000 cycles.

It is particularly notable that the materials of the present inventionhave particle sizes which are significantly greater than those of thenanoscale materials of the prior art and yet provide distinctly superiorperformance. Measurements of crystallite size of the present materialsand prior art nanoscale lithium titanate materials were made from X-raydiffraction data. The prior art nanoscale lithium titanate material hada crystallite size of approximately 34 nm. The pristine material of thepresent invention had a crystallite size of approximately 196 nm, whilethe composite material of the present invention had a crystallite sizeof approximately 170 nanometers.

The morphology of the material of the present invention was furtherinvestigated through a series of measurements of pore size distributioncarried out by the method known in the art as mercury intrusion. Poresizes were measured and data analyzed by graphing results of themeasurement in term of pore size diameter versus log differentialintrusion in units of milliliters per gram. Measurements were carriedout on prior art nanoscale material, prior art conventional material andon both pristine and composite material of the present invention asdescribed above. Pore size diameters for the conventional material andthe two materials of the present invention had a primarily bimodaldistribution with a first group of pores corresponding to pores formedbetween the primary particles of the material. A second distributioncorresponded to pores formed between aggregates of the primaryparticles. The nanoscale material had a significant third distributionof pores corresponding to second order agglomerates, that is to saypores formed between agglomerates.

The data establishes that the materials of the present invention have alower degree of agglomeration than the conventional material.Furthermore, the prior art nanoscale material has a very high degree ofagglomeration showing a significant second order agglomeration.Specifically, as evaluated in this series, the pristine material of thepresent invention has a pore distribution in which approximately 50% ofthe pores are in the 0.1-1.0 micron range corresponding to pores betweenprimary particles, and approximately 30-35% of the pores are in the sizerange of 1-100 microns corresponding to pores between agglomerates. Theadditive based, composite material of the present invention showed astill higher degree of primary porosity with approximately 55% of thepores being in the 0.1-1.0 micron range and approximately 25-35% of thepores being in the 1-100 micron range. In comparison, conventionalmaterials showed approximately 40% of porosity being in the primaryrange and approximately 35-40% of the porosity being in the 1-100 micronrange indicative of agglomerates.

By contrast, the prior art nanoscale material showed only 11% ofporosity being in the primary range, which in this instance was0.003-0.03 microns. 67% of the porosity of the nanoscale material was inthe 0.03-0.4 micron range attributable to agglomerates, andapproximately 20% of the porosity was in the second order agglomeraterange of 0.4-180 microns.

In a further series of evaluations, the surface area of the materialswas measured by the BET method, and particle size was determined inthree different methods. In the first method, the BET spherical particlesize of the materials was determined using the formuladiameter=6/(surface area×density) where density of the lithium titanatewas assumed to be 3.50 g/cm³. In a second method, particle size wasdetermined from measurements made by scanning electron microscopy (SEM),and in a third method, the particle size was determined frommeasurements made by transmission electron microscopy (TEM). The SEMimages are shown in FIG. 6 and TEM images are shown in FIG. 7. As willbe seen, materials of present invention show the forms of lowagglomeration, where the composite material particles are more facetshaped than are the pristine material particles. Some particles ofpresent materials show the forms of necks that indicate early-stagesintering (but not fully sintering) of particles (see arrow in FIG. 7).The early-stage sintered particles may form the agglomerate structure asdescribed above and provide better electronic conductivity paths thanisolated particles, which can improve the rate capability. The surfacearea and particle size data from this series of tests is summarized inTable 1 hereinbelow. As will be seen, materials of the present inventionhave relatively large particle sizes and relatively low surface areas ascompared to prior art nanoscale lithium titanate materials; yet, asshown above, the materials of the present invention provide performancecharacteristics far superior to those of the prior art.

TABLE 1 BET surface BET spherical SEM particle TEM particle Sample area(m²/g) particle size (nm) size (nm) size (nm) Prior art nano LTO 60.0 2940 20 Present pristine LTO 4.2 408 350 250 Present composite LTO 5.5 309300 200

In general, the materials of the present invention have particle sizeswhich are greater than 100 nanometers, and more particularly greaterthan 150 nanometers. All particle size measurements may depend to somedegree upon methods by which such measurements are made. In general, theparticles of the present invention will not be below this size range,and in specific embodiments, will typically be in the range of 150-500nanometers. The surface area of materials of the present invention isgenerally no more than 20 m²/g, and in particular instances no more than15 m ²/g. In specific instances, the surface area is in the range of 3-7m²/g, with all surface area measurements herein being as measured by theBET method. The structure of the material is such that the primaryparticles have a lower degree of agglomeration as compared to prior artmaterials. In this regard, in a typical material, 45-60% of the porositywill be attributable to spaces between primary particles. In thisregard, this porosity will be in the general size range of 0.1-1.0microns, and in particular instances 0.2-0.6 microns. In materials ofthe present invention, the porosity attributable to agglomerates of theprimary particles will be lower than the primary porosity. In a typicalmaterial, 25-40% of the porosity will be attributable to theagglomerates, and this porosity will generally have a size in the rangeof 1-100 microns, and in particular instances 5-50 microns. In general,the degree of porosity attributable to the primary particles will behigher in the materials of the present invention as compared to priorart materials. While not wishing to be bound by speculation, it isbelieved that the pore size of the first distribution may contribute tohigh rate capability, and the second distribution of pore sizes maycontribute to good electrolyte wetting, both of which are essential tohigh quality performance. It has been found that, in general, thecomposite materials of the present invention have slightly lower degreesof agglomeration than do the pristine materials, and in this regard havea generally higher percentage of porosity in the first distribution ascompared to pristine materials. Micrographic data also suggests that thecomposite materials have a more faceted particle structure.

In a measurement made by SEM image analysis, the electrodes whichinclude materials of the present invention show higher porosity than theelectrodes including prior art materials (as shown in FIG. 8). Forinstance, an electrode including pristine material of present inventionhas a porosity of 25% and an electrode including composite material ofpresent invention has a porosity of 33%. While an electrode includingprior art conventional material has a porosity of 2% and an electrodeincluding prior art nano material has a porosity of 6%.

From the foregoing, it will be understood that materials of the presentinvention, both pristine and composite, can be prepared so as to combinerelatively large particle sizes with very high performancecharacteristics. In accord with the teachings presented herein, suchmaterials may be readily prepared and utilized by those of skill in theart.

As will be seen, the present invention provides high quality lithiumtitanate materials. The materials of the present invention haveproperties which allow for the fabrication of lithium batteries whichare stable, efficient, and capable of reliably delivering very highlevels of power. These properties, together with the low costs achievedthrough the use of the previous disclosed methods (U.S. patentapplication Ser. No. 11/757,659, June 2007), make this technologyparticularly advantageous for the manufacture of high power batterysystems such as those used in electric vehicles, large power tools,power backup systems, and the like.

While the invention has been described with reference to particularlithium titanate materials, it is to be understood that it may beutilized for the preparation of other alkali metal titanates. Also,while specific composite lithium titanate materials incorporated withtransition metals have been described, it is to be understood that thepresent invention is broadly applicable to pristine and compositematerials, and in those instances where composite materials areutilized, additives other than transition metals may be utilized.

In view of the teaching presented herein, further modifications andvariations will be apparent to those of skill in the art. Accordingly,the foregoing is understood to be an illustration, but not a limitation,upon the practice of the invention. It is the claims, including allequivalents, which define the scope of the invention.

1. A lithium titanate material comprised of aggregates and agglomerationof particles, said particles having an average size of more than 100 nmand a surface area of no more than 20 m²/g as measured by the BETmethod.
 2. The material of claim 1, wherein said particles have anaverage size of more than 150 nm.
 3. The material of claim 1, whereinsaid particles have an average size in the range of 150-500 nm.
 4. Thematerial of claim 1, wherein the surface area of said material, asmeasured by the BET method, is less than 15 m²/g.
 5. The material ofclaim 1, wherein the surface area of said material, as measured by theBET method, is in the range of 3-7 m²/g.
 6. The material of claim 1,wherein said particles have a crystallite size, as measured by XRD, ismore than 100 nm.
 7. The material of claim 1, wherein said particleshave a crystallite size, as measured by XRD, is in the range of 150-250nm.
 8. The material of claim 1, wherein said material has a pore sizedistribution such that it includes a first distribution of pore sizes inthe range of 0.1-1 micron, and a second distribution of pore sizes inthe range of 1-100 microns.
 9. The material of claim 8, wherein thevolume of the pores in said first distribution is greater than thevolume of the pores in said second distribution.
 10. The material ofclaim 8, wherein the first distribution of pore sizes are in the rangeof 0.2-0.6 micron.
 11. The material of claim 8, wherein the seconddistribution of pore sizes are in the range of 5-50 microns.
 12. Thematerial of claim 1, further including an additive.
 13. The material ofclaim 12, wherein the inclusion of said additive results in one or moreof following: reducing the particle size of said material, reducing thecrystallite size of said material, increasing the surface area of saidmaterial, producing more separated particles of said material, producingmore faceted particles of said material, and improving the ratecapability of said material.
 14. The material of claim 12, wherein saidadditive is a transition metal.
 15. The material of claim 14, whereinsaid transition metal is selected from the group consisting of V, Zr,Nb, Mo, Mn, Fe, Cu, Co, and combinations thereof
 16. The material ofclaim 12, wherein said additive comprises Zr.
 17. The material of claim12, wherein said additive comprises 0.01-20 weight percent of saidmaterial.
 18. The material of claim 12, wherein said additive comprises0.1-5 weight percent of said material.
 19. An electrode which includesthe material of claim
 1. 20. The electrode of claim 19, wherein theporosity of said electrode prior to calendering is in the range of10-50%, as measured by SEM image analysis.
 21. The electrode of claim19, wherein the porosity of said electrode prior to calendering isgreater than 20%, as measured by SEM image analysis.
 22. A battery whichincludes the electrode of claim 19.